An important objective of de novo protein design is the preparation of metalloproteins, as many natural systems contain metals that play crucial roles for the function and/or structural integrity of the biopolymer. [1,2] Metalloproteins catalyze some of the most important processes in nature, from energy generation and transduction to complex chemical transformations. At the same time, metals in excess can be deleterious to cells, and some ions are purely toxic, with no known beneficial effects (e.g., Hg II or Pb II ). Ideally, we would hope to be able to use an approach based on first principles to create both known metallocenters and novel sites, which may lead to exciting new catalytic transformations. However, the design of novel metalloproteins is a challenging and complex task, especially if the aim is to prepare asymmetric metal environments.Numerous metalloprotein systems have been designed over the past 15 years, typically through the use of unassociated peptides that assemble into three-stranded coiled coils or helix-loop-helix motifs that form antiparallel fourstranded bundles. In terms of metal-ion binding, these systems have been functionalized with heme [3,4] and nonheme mononuclear [5] and binuclear centers. [6,7] It is often difficult to prepare nonsymmetrical metal sites through these strategies owing to the symmetry of the systems, which rely on homooligomerization. Thus, the preparation of a single polypeptide chain capable of controlling a metal-coordination environment is a key objective.Previously, we designed soft, thiol-rich metal-binding sites involving cysteine and/or penicillamine as the ligating amino acid residues into the interior of parallel, three-stranded ahelical coiled coils. [8,9] These systems have served as hallmarks for understanding the metallobiochemistry of different heavy metals, such as Cd II , Hg II , As III , and Pb II . [8][9][10][11] We have shown how to control the geometry and coordination number of metals such as Cd II and Hg II at the protein interior and how to fine-tune the physical properties of the metals, which led to site-selective molecular recognition of Cd II . [12][13][14] Although these homotrimeric assemblies have been very useful, the production of heterotrimeric systems in which metal environments could be fine-tuned controllably or a hydrogen bond could be introduced site-specifically has been elusive. [15] Therefore, we chose an alternative strategy to satisfy this objective and used a single polypeptide chain instead of multiple self-associating peptides.Existing designed heteromeric helical bundles and coiled coils show energetic preferences of several kcal mol À1 for the desired heteromeric versus homomeric assemblies. [16,17] However, the energy gap between a hetero-and homomeric assembly often depends critically on ionic strength, the pH value, and other environmental parameters. Moreover, the objective of many studies in de novo protein design is to make the metal ion adopt an energetically suboptimal coordination geometry, and the degree t...
